DE102010054871A1 - Powertrain for motor vehicles - Google Patents

Abstract

The invention relates to a drive train for a motor vehicle with at least one driven axle, which has a differential and at least two vehicle wheels that are operatively connected to one another via the differential, the drive train furthermore with a first drive unit and with a second drive unit, the second drive unit having an electric motor, whose drive shaft is aligned at least axially parallel to a pinion shaft.

Description

Field of the invention

The invention relates to a drive train for a motor vehicle having at least one driven axle which has a differential and at least two vehicle wheels operatively connected to each other via the differential, the drive train further comprising a first drive unit and a second drive unit, the second drive unit having an electric motor whose drive shaft is aligned at least axially parallel to a pinion shaft.

Background of the invention

DE 10 2004 024 086 A1 shows such a drive device for motor vehicles with a main drive unit and with two electric drive units. A first electric drive unit has an electric motor as a drive, which acts directly on a drive shaft, because its rotor shaft is the drive shaft. The second electric drive unit is a torque vectoring unit and has an electric motor as a drive and a superposition gear, which is operatively connected to a rear differential.

Drive of the main drive unit, for example, an internal combustion engine, which forms the drive unit with a change gear and which is operatively connected via the change gear with the drive shaft and via this with the rear differential. Alternatively, the drive shaft may be connected to a transfer case, which is also part of the main drive unit and which distributes torque in a drive train between two driven vehicle axles.

The drive shaft is a pinion shaft of an angle drive, via which the main drive unit and the first electric drive unit are connected to the input of the rear differential. The ring gear of the angle drive is input shaft of the transverse differential, via which the torques are distributed to two outputs. Each of the outputs (output shafts) of the differential formed as a planetary gear is in operative connection with a driven vehicle wheel of the rear axle. Each vehicle wheel is in operative connection with the other drive wheel on the rear axle, which can be influenced by the torque vectoring unit.

On the drive shaft can be applied via the electric motor of the first electric drive unit in addition to the main drive unit power and introduced via the angle drive in the differential. In other cases, where the drive power of the electric motor is not needed, it can be used to recover energy when the drive shaft entrained by the drive or by overrun, the rotor is driven by it and the electric motor is connected as a generator.

DE 10 2008 029 287 B4 shows a drive train with two drivable axles for motor vehicles. The vehicle has a first drive unit with which a first axle is permanently driven. The first drive unit preferably provides an internal combustion engine and a first transverse differential operatively connected thereto which acts on two driven vehicle wheels of the first axle.

An electric second drive unit is arranged in the region of a second axis. Drive of the second drive unit is an electric motor, which forms the second drive unit with a planetary gear and with a clutch pack. The axis of rotation of the drive shaft, which is the rotor shaft of the electric motor, is arranged parallel, preferably coaxially, to a pinion shaft, designated as an input shaft, of an angle drive. The second axle has two driven vehicle wheels, which are operatively connected to a second transverse differential. The output of the electric drive unit is located on a side facing away from the second transverse differential side. The first axle is driven exclusively by the first drive unit and the second axle exclusively by the second drive unit.

The drive shaft of the electric drive unit is formed by a hollow shaft, which is the rotor shaft of the electric motor. The pinion shaft is arranged concentrically in the hollow shaft. The hollow shaft is connected to the clutch pack and is still in operative connection with the planetary gear, which is driven by the clutch pack. The mounted on the planet carrier planetary gears of the planetary gear are meshing with a sun, which is rotatably connected to the drive shaft. About clutches of the clutch pack can be either rotationally fixed connections between a planet carrier of the planetary gear via the clutch pack to the drive shaft or directly to the drive shaft of the Make electric motor out, so that a switchable two-speed geared connection between the electric motor and the pinion shaft is formed.

The pinion shaft is meshing with a ring gear, which is connected to the input of the transverse differential. The input, ie the input shaft, of the differential is the differential cage of the classic bevel gear differential, from which torque is distributed to two outputs (output shafts) via differential gears. Each output is in operative connection with a driven vehicle wheel of the second axis, so that the vehicle wheels are also in operative connection with each other through the naturally compensating effect of the bevel gear differential via the output shafts.

Description of the invention

The object of the invention is to provide a drive train, which preferably has two driven axles, with two drive units as variable and at the same time energy-saving as possible.

The object is solved according to the features of claim 1.

The invention provides a drive train for a motor vehicle with at least one driven axle which has a differential and at least two vehicle wheels which are operatively connected to one another via the differential. The axle is either a front axle or a rear axle of the vehicle. The drive train has at least one first drive unit and a second drive unit. The second drive unit has as drive to an electric motor, the drive shaft is aligned at least axially parallel to a pinion shaft and engages the pinion shaft. The term paraxial includes coaxial or concentric arrangements.

The invention encompasses arrangements in which the drive shaft, that is, the rotor shaft of the electric motor of the second drive unit, is arranged parallel to the pinion shaft at a distance and connected in a geared manner to the latter. Gear connections are, for example, belt drives or chain drives or gear drives with gear stages or planetary drives. Alternatively, the drive shaft and the pinion shaft are coaxial with each other by these merge integrally with each other with a common axis of rotation or fixed or separable connected to each other. The invention also includes arrangements in which one of the shafts, either the rotor shaft of the electric motor or the pinion shaft, is designed as a hollow shaft and the other of these shafts is arranged concentrically in the hollow shaft. Finally, the invention also includes arrangements in which the rotor of the electric motor of the second drive unit is arranged directly concentrically on the pinion shaft, that is, the pinion shaft is simultaneously the rotor shaft.

The pinion shaft is part of an angle drive, which is formed by a pinion on the pinion shaft and a ring gear. The ring gear engages an input shaft of the differential. The input shaft of the differential is the sum shaft at which the largest torques are applied and via which the power applied by the drive units power is introduced to the compensation assembly in the differential. The pinion meshes with the ring gear so that power applied to the pinion shaft by the second drive unit is applied to the input shaft of the differential via the angle drive. Input shafts are preferably planetary carriers for planetary differentials, and ring gears for differentials with torque vectoring units.

According to the invention, the pinion shaft is also operatively connected to the first drive unit. The operative connection is made, for example, via a drive-shaft or via another shaft. The invention includes arrangements in which the shaft, so the connection to the first drive unit, arranged in parallel with distance to the pinion shaft and geared to this as already described above the example of the compound of pinion shaft and rotor shaft. Alternatively, the shaft and the pinion shaft are coaxial with each other, by integrally merging with each other with a common axis of rotation or fixed or separable connected to each other. The invention also includes arrangements in which one of the shafts is designed as a hollow shaft and the other of these shafts is arranged concentrically in the hollow shaft.

The invention further provides that in the operative connection between an output shaft of the differential and one of the vehicle wheels an engageable and disengageable clutch is arranged. When disengaged clutch the non-rotatable operative connection between the output shaft and the vehicle is broken. Thus, the compensating operative connection between the vehicle wheels is repealed, because by the differential effect and the other of the output shafts can no longer transmit torques. The vehicle wheels of the axle are thus separated from the power flow of the drive train.

The advantage of the invention is that although the disengaged clutch, the driven rear axle is disconnected from the power flow, but the drive power of the second drive unit can be used to superimpose, for example, the drive power of the first drive unit, because the pinion shaft both with the drive of the first drive unit is also operatively connected to the drive of the second drive unit. This makes it possible, for example, to supply the drive power of the second drive unit in addition to the drive power of the first drive unit to a second axle with driven wheels. Alternatively, in this switching state of the clutch, it is possible to switch off the drive of the first drive unit and to introduce power into the drive train only with the drive of the second drive unit in order, for example, to drive the second axle.

Another advantage of the invention is due to the arrangement of the coupling between the vehicle wheel and the differential, which consists in that at this point a rotationally fixed connection is disconnected at the only moments of one of the drive wheels and not the relatively high driving torques at the input of the differential or abut against the pinion shaft and thus the coupling can be dimensioned according to space saving.

An embodiment of the invention provides that on the driven axle on both sides of the differential, the respective operative connection between the output shaft and the vehicle by each clutch is separable. By simultaneously disengaging both clutches on the axle symmetrical conditions are created by complete separation of the two driven vehicle wheels in the drive train behind the differential. The clutch (s) are either integrated in the housing of the differential or are integrated into the respective compound of the differential and the vehicle wheels via cardan shafts. Alternatively, the respective coupling sits between the wheel and a drive shaft.

By engaging the clutch (s), the operative connection between the two wheels and thus the action of the differential on the driven first axis is restored and the drive power of the second drive can be returned to the first axis.

It is conceivable that between the first drive unit and the pinion shaft, a separating clutch is arranged, with which the operative connection between the first drive unit and the pinion shaft and thus between the first drive unit and the first axis can be selectively separated or restored. When this operative connection is disconnected, the first axle can only be driven by means of the second drive unit or not at all. In the latter case, the drive of the second drive unit can be completely switched off or switched in overrun mode as a generator.

An embodiment of the invention provides that the operative connection between the drive of the second drive unit and the pinion shaft can be repeatedly separated and restored with a disconnect clutch. In the event that the drive power of the second drive in the drive train is not needed this can be completely separated from the drive train. In this case, the drive shaft of the second drive, such as the rotor shaft of an electric motor, energy-saving not entrained.

A further embodiment of the invention provides that the second drive unit has at least one gear in the operative connection between the drive shaft of the electric motor and the pinion shaft, so that z. B. reduced speed of the rotor shaft and higher torques can be applied to the pinion shaft. The second drive unit also preferably has a clutch, with the gears of the preferably at least two-speed transmission can be switched.

Description of the drawing

1 shows schematically and not to scale a drive train 1 for an otherwise not further illustrated motor vehicle two driven axles 2 and 3 , The axis 2 has a classic designed as a bevel gear differential 4 and two vehicle wheels operatively connected via the differential 5 and 6 on. The powertrain 1 is still with a first drive unit 7 and with a second drive unit 8th Mistake.

The second drive unit 8th has an electric motor 9 on, whose drive shaft 9a is designed as a hollow shaft and in the concentric and thus axially parallel to a pinion shaft 10 is arranged. Between drive shaft 9a and pinion shaft 10 is by means of a clutch engageable and disengageable 11 and a two-speed switchable transmission 12 formed an operative connection, via which the drive shaft 9a at the pinion shaft 10 attacks. The drive shaft 9a can do this by means of the clutch 11 optionally with the ring gear 12a or the sun wheel 12b be connected, each with planetary gears 12c in mesh. Output of the drive unit 8th is the planet carrier 12d , which is rotatably connected to the pinion shaft. The connection between the pinion shaft 10 and the drive shaft 9a can by means of the coupling 11 also be completely separated.

The pinion shaft 10 has a pinion head 10a which meshes with a ring gear 13 an angle drive stands. The ring gear 13 is with the input shaft of the differential 4 in the form of a differential basket 4a connected in the differential gears 4b are rotatably mounted, with output wheels 4c of the differential meshing. The driven wheels 4c sit on output shafts 14 , Between each of the output shafts 14 and one of the vehicle wheels 5 and 6 is in each case a clutch engageable and disengageable 15 arranged.

The axis 3 is also a driven axle with vehicle wheels 3a and 3b that with a drive 16 the first drive unit 7 is operatively connected, which is for example an internal combustion engine. The drive unit 7 points out of the drive 16 another change gear 17 and a transfer case 18 via which an operative connection to a connecting shaft 19 , which can be a cardan shaft, is made. About the connecting shaft 19 is the first drive unit 7 with the pinion shaft 10 rotatably connected, wherein it is not excluded that the first drive unit 7 and the pinion shaft 10 are separable from each other by a clutch.

By disengaging only one of the clutches 15 can the axis 2 from a powertrain power flow 1 be separated. In that case, it is optionally possible the axis 3 by operating the electric motor with the clutch engaged 11 and in two different gear ratios of the transmission either with only the drive unit 8th to drive or that of the drive 16 to the axis 3 guided torques with those of the drive unit 8th to overlay. reference numeral 1 powertrain 12d planet carrier 2 driven axle 13 crown 3 driven axle 14 output shaft 3a vehicle 15 clutch 3b vehicle 16 drive 4 differential 17 change gear 4a differential cage 18 Transfer Case 4b pinion 19 connecting shaft 4c output gear 5 vehicle 6 vehicle 7 first drive unit 8th second drive unit 9 electric motor 9a drive shaft 10 pinion shaft 10a pinion head 11 clutch 12 transmission 12a ring gear 12b sun 12c planet

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 102004024086 A1 [0002]
• DE 102008029287 B4 [0006]

Claims (7)

Powertrain ( 1 ) for a motor vehicle with at least one driven axle ( 2 ), which is a differential and at least two vehicle wheels operatively connected to one another via the differential ( 5 . 6 ), the drive train ( 1 ) with a first drive unit ( 7 ) and with a second drive unit ( 8th ), wherein the second drive unit ( 8th ) an electric motor ( 9 ), whose drive shaft ( 9a ) at least axially parallel to a pinion shaft ( 10 ) and with the pinion shaft ( 10 ) which is connected to one of the differential ( 4 ) engaging ring gear ( 13 ) is in meshing engagement and which with the first drive unit ( 7 ) is operatively connected, and wherein between at least one output shaft ( 14 ) of the differential ( 4 ) and one of the vehicle wheels ( 5 . 6 ) an engageable and disengageable coupling ( 15 ) is arranged. Drive train according to claim 1, in which a further axis ( 3 ) with driven wheels ( 3a . 3b ) is provided, which with a drive ( 16 ) of the first drive unit ( 7 ) is operatively connected. Drive train according to claim 2, in which the electric motor ( 9 ) via the pinion shaft ( 10 ) with the first drive unit ( 7 ) is operatively connected. Drive train according to claim 1, in which the second drive unit ( 8th ) at least one coupling ( 11 ) in an operative connection between a drive shaft ( 9a ) of the electric motor ( 9 ) and the pinion shaft ( 10 ) having. Drive train according to claim 1, in which the second drive unit ( 8th ) at least one transmission ( 12 ) in an operative connection between a drive shaft ( 9a ) of the electric motor ( 9 ) and the pinion shaft ( 10 ) having. Drive train according to Claim 1 or 5, in which the second drive unit ( 8th ) with an engageable and disengageable coupling ( 11 ) provided switchable at least two-speed transmission ( 12 ) having. Drive train according to claim 1, in which between a further output shaft ( 14 ) of the differential ( 4 ) and one of the vehicle wheels ( 5 . 6 ) an engageable and disengageable coupling ( 11 ) is arranged.

Images